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It’s hard to believe that
a year has already gone by
since I last wrote for this news-
letter. In what seems to have
become the usual pace, there
have been a number of happy
developments.
We spent a great deal of time
and effort preparing for our
septennial External Review.
You can find the details of this on page 6, but
the bottom line is that a committee of three dis-
tinguished physics faculty from outside UCSB
came away with a positive impression of what
we have been able to accomplish in the past
seven years, and where we are going in the
future (though, as always, challenges remain).
Our faculty continued to set a blistering pace of
awards and accomplishments, including induc-
tion into the National Academy of Sciences for
David Awschalom, bringing the number of cur-
rent and emeritus faculty in our Department
who are members of this august body to dou-
ble digits. Sergei Gukov (whom I wrote about
in this space last time as one of our new faculty
in mathematical physicists) and Tommaso Treu
(a member of our small but very active group
of observational astrophysics) each received the
prestigious Alfred P. Sloan Research Fellowship.
Tommaso also received the David and Lucile
Packard Fellowship, one of just 20 awarded
nationwide throughout the sciences and engi-
neering. This continues a strong tradition in our
Department: Leon Balents, Jean Carlson, and
Crystal Martin all received the Packard Fellow-
ship in recent years. (We are grateful to these
private foundations for their visionary support
of young scientists.) More details on further fac-
ulty and student awards can be found inside.
We welcome three new members of our
Department, though none are new to UCSB.
Frank Brown and Joan-Emma Shea have been
faculty in the Department of Chemistry and
Biochemistry for several years. Their research
interests spill over into physics, and so we were
grateful when they accepted our offer of par-
tial appointments in Physics. Chetan Nayak is
a Senior Researcher at Microsoft’s Station Q
facility, dedicated to the study of quantum com-
puting and housed at UCSB. Formerly on the
faculty at UCLA, he has now joined our Depart-
ment as a faculty member.
We hope to welcome still more faculty in the
near future. We are currently running searches
for new faculty in no less than five areas: experi-
mental astrophysics, experimental biophysics,
experimental condensed-matter physics, theo-
retical condensed-matter physics, and theoretical
elementary-particle physics. Success in these
searches would enable us to broaden and
strengthen our research and teaching program,
which will be essential if we are to maintain our
leadership in the new century. Our Department
has always been one of the smallest among the
top-ranked institutions, and so careful planning
is needed as we go forward.
Mark Srednicki Department Chair UCSB Physics
F A L L 2 0 0 7
Fro
m t
he
Ch
air
Faculty NewsAppointments
2
Awards and Honors
Joan-Emma Shea also holds a joint position with the Departments of Chemistry/Biochemistry and Physics. She received her BSc in Chemistry from McGill University, Canada in 1992 and her PhD in Physical Chemistry from MIT in 1997. She pursued her postdoc-toral studies jointly in the Department
of Computational Biophysics and Chemistry at the Scripps Research Institute and in the Department of Physics at UCSD. After a year as an assistant professor of chemistry at the University of Chicago, Dr. Shea joined the Chemistry fac-ulty at UCSB in 2001. Dr. Shea is the recipient of an National Science Foundation CAREER award, an AP Sloan Fellowship and a Packard Fellowship.
Research in the Shea group focuses on developing and applying the techniques of statistical and computational physics to the study of biological problems. Current work involves the investigation of cellular processes such as in-vivo protein folding and protein aggregation.
David Gross, director of UCSB’s Kavli Institute for Theoretical Phys-ics and co-recipient of the 2004 Nobel Prize in Physics, was elected a fellow of the American Philo-sophical Society (APS), the oldest learned society in the country, in the spring of 2007.
Professor Gross was also elected as Honorary Fellow of the Indian Academy of Science in Bangalore, India, and For-eign Fellow of the Indian National Science Academy.
Professor Gross also was bestowed the honor of Doctor Philosophiae Honoris Causa at Sao Paulo University, Brazil, in 2006, and at Ohio State University in 2007.
David Awschalom was elected as one of the 72 new members of the National Academy of Sciences, in recognition of his distinguished and continuing achievements in original research.
The National Academy of Sciences is a private organization of scientists
and engineers dedicated to the furtherance of science and its use for the general welfare. It was established in 1863 by a congressional act of incorporation signed by Abra-ham Lincoln that calls on the Academy to act as an official adviser to the federal government, upon request, in any matter of science or technology.
Chetan Nayak is a Professor in the Physics Department as well as Senior Researcher in Microsoft Station Q, a UCSB research group working on topological quantum computing. The group combines researchers from math, physics and computer science.
Frank Brown holds a joint position with the Departments of Chemistry/Biochemistry and Physics. He received his BS in Chemistry and BA in Applied Mathematics from UC Berkeley and his PhD in Physical Chemistry from MIT in 1998. He was a National Science
Foundation Postdoctoral Fellow at UC San Diego and a Yen Fellow at the University of Chicago before joining the UCSB Chemistry faculty in 2001. Dr. Brown is an AP Sloan Research Fellow and was awarded the Presidential Early Career Award in Science and Engineering in 2005.
His research group’s interests lie at the interface between physical chemistry and biophysics and they use a variety of tools spanning the traditional fields of statistical mechanics, hydrodynamics, elasticity theory and quantum mechanics in their research efforts.
He received his BA in Physics from Harvard and his PhD in Physics from Princeton in 1996. He was a post-doctoral fellow at UCSB’s Kavli Institute for Theoretical Physics before joining the faculty at UCLA, where he received an AP Sloan Foundation fellowship and an National Science Foundation Early Career award. He joined Station Q in 2005 and the Physics Department in 2007.
His research interests are in the condensed matter physics of strongly-correlated electronic materials, especially high-tem-perature superconductors and the quantum Hall effect. His current research focuses on the application of topological phases of electrons to quantum computation.
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Awards and Honors continued
Faculty NewsNews
Alan Heeger, UCSB Physics profes-sor and Nobel recipient for the 2000 Prize in Chemistry, was awarded the Eni Italgas Prize on Energy and Envi-ronment for his innovative research on solar cells made with plastic mate-rial: cheap, versatile and clean. The
shared prize is awarded to scientists who have achieved relevant results in research on energy sources and their relation with the environment.
“Elementary particle physics is at a
crossroads,” says Joseph Incandela.
A new giant particle accelerator, the
Large Hadron Collider (LHC), will be
coming online in 2008 at the European
Center for Nuclear Research (CERN)
in Geneva, Switzerland. The LHC will
open up the exploration of the properties of matter down
to distance scales of 10 -19 meters. Many physicists believe
that at this length scale new physics processes could
begin to manifest themselves, and that we may be on the
threshold of a revolution in our understanding of matter
and its interactions.
Two large international collaborations of thousands of
physicists each have almost completed construction of
two giant detectors to study particle collisions at the LHC.
The UCSB experimental high energy physics group has
been heavily involved in this program for many years.
This year, Professor Incandela was elected Deputy Anal-
ysis Coordinator for the Compact Muon Solenoid (CMS)
collaboration. This summer he moved with his family to
Geneva to take on this new important responsibility in
the management of the scientific program of the experi-
ment. Professor Incandela’s stay at CERN will last about
two years; during that time, he will continue to work with
UCSB graduate students and postdocs, some of whom are
now in Switzerland with him.
Sergei Gukov and Tommaso Treu were awarded 2007 Sloan Research Fellowships in Science and Technol-ogy. These awards are intended to enhance the careers of the very best young faculty members in specified fields of science.
Professor Treu was also selected as one of twenty recipients nationwide of the Packard Fellowship for Science and Engineering for 2007.
In the fall, an international team of sci-entists led by Treu and UCSB Physics postdoctoral fellow Phil Marshall identi-fied a tiny galaxy nearly halfway across
the universe -- the smallest in size and mass known to exist at that distance.
In June, Treu was awarded a UCSB Regents’ Junior Faculty Fellowship Award, for support of his project “The duty-cycle of supermassive black holes: X-raying Virgo.”
In the spring, he was among the recipients of the National Science Foundation’s prestigious Faculty Early Career Development (CAREER) Program awards for his project “Dark Matter and Black Holes Over Cosmic Time”.
David Cannell, together with
Professor Marzio Giglio from the Uni-
versity of Milan, were responsible for
The Gradflex experiment (GRAdient-
Driven FLuctuations EXperiment),
which was flown aboard the Euro-
pean Space Agency’s Foton-M3
mission, after about 6 years of development.
Launched from the Baikonur Cosmodrome in Kazakhstan,
the spacecraft carried a payload of 43 experiments in a
range of disciplines – including fluid physics, biology, crys-
tal growth, radiation exposure and exobiology. The satellite
returned to Earth in Kazakhstan after 12 days in orbit. With
the equipment safely back on Earth, further experiments
and extensive data analysis will continue.
Jeff Richman, along with five other
UCSB faculty, was named a Fellow
of the American Association for the
Advancement of Science (AAS) in fall
2007 for contributions to the field
of elementary particle physics, par-
ticularly for experiments exploring
the physics of heavy quarks and the
source of matter-antimatter asymmetry.
Most of the normal matter in the universe appears to reside in a dilute gas between the galaxies. Its presence there poses a
puzzle. If influenced by gravitational forces alone, over half of it would have fallen into galaxies and formed stars long ago.
How the gas is kept out of galaxies is not really understood. The discovery of elements heavier than helium in this inter-
galactic gas, however, points to at least some circulation of material between galaxies and the intergalactic medium. Such
circulation could play a key role in determining the properties and lifecycle of galaxies.
The normal matter in the universe is made mostly of the simplest elements, hydrogen and helium (see sidebar, page 5).
Most of the latter, we now know, was produced in large quantities when the universe was still a three-minute-old fireball.
This nuclear fusion also created trace amounts of lithium, beryllium, and boron, but it is believed that all of the heavier ele-
ments, carbon and oxygen most abundant among them, were synthesized by stars much later. The standard model for
star formation requires high density gas clouds, and as far as we know, these conditions only occur deep inside galaxies.
This is why heavy elements in the intergalactic gas indicate exchange of material
between galaxies. Stars return the products of nucleosynthesis to the surround-
ing gas via stellar winds and explosions, but considerable energy and momentum
would have to be imparted to this material to free it from the gravitational grip of
the galaxy. How then did the heavy elements reach the intergalactic medium? A
team of UCSB researchers led by Professor Crystal Martin is trying to unravel the
mysteries of how gas gets into and out of galaxies.
Over ten years ago, Professor Martin and her collaborators began looking for
signs of galactic winds in nearby galaxies. At that time, simple physical arguments
suggested that the energy released by tens of thousands of supernova explosions
could raise the gas pressure enough to blow the gas out of small galaxies. The
ensuing outflow of material might plausibly be enriched with heavy elements
synthesized by massive stars. Theoretical models could not, however, predict the
efficiency of these winds due to the complexity of the interaction of the expand-
ing debris with the surrounding gas. Measurements would be essential. Professor
Martin and collaborators at the Johns Hopkins University and the University of
Wyoming obtained some of the first observations with the Chandra X-Ray Observatory, a satellite with unprecedented reso-
lution for imaging soft X-rays, and found direct evidence for supernova-driven winds emerging from some galaxies.
By analyzing the distribution of photon energies (that is, the X-ray spectra), Martin and her collaborators showed that the
material being ejected from the galaxies in galactic winds was in fact enriched with heavy elements. They also found that the
galaxies with galactic winds had recently formed many new stars. Since massive stars have relatively short lives, these galactic
wind galaxies have much higher concentrations of massive stars, and
therefore Type II supernova explosions, than a typical galaxy. These
bursts o f activity are brief by galactic standards, but we know they were
more common in the distant past. The starburst phase is thought to be
triggered by tidal interactions between galaxies and/or direct collision s
of galaxies. The relatively short lives of very massive stars mean that tens
of thousands of supernova explosions occur soon after the interaction.
The team showed that the synchronization of so many explosions raised
the pressure in the galactic gas enough to enable the most enriched gas
to escape, removing a large fraction of the newly synthesized heavy elements from the galaxy. Their pictures of this process
also showed why the theoretical models over-estimated how much these winds would disturb the galactic gas reservoir. The
outflows were not spherical; they erupted perpendicular to the gaseous galactic disk leaving part of this disk intact.
Faculty Focus: Galactic WindsCrystal Martin ]
Composite image of galactic wind from the dwarf galaxy NGC 1569. The galaxy is passing through a brief evolutionary phase of intense star formation triggered by the close passage of another small galaxy.Photo: Martin, Kobulnicky, & Heckman, 2002. Courtesy of NASA/CXC/SAO.
Crystal Martin’s research group: www.physics.ucsb.edu/~cmartin
Chandra X-Ray Observatory: chandra.harvard.eduChandra X-Ray Center is operated for NASA by the Smithsonian Astrophysical Observatory.
Thirty Meter Telescope: www.tmt.org
W.M. Keck Observatory: www.keckobservatory.org
RELATED LINKS
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UCSB Physics graduate student Kurt Soto looking into the mirror of one of two Keck telescopes, the largest optical telescopes in the world. These telescopes can now be operated from the UCSB campus remotely. The primary is constructed f 36 hexagonal mirrors held in alignment to nanometer accuracy by actuators and active compensation. These telescopes were designed and built by the collaborative leadership of University of California and CalTech astronomers and funded by a generous gift from the W. M. Keck Foundation.
[continued on page 11]
The discovery of these galactic winds incited much thought about their influence on galaxy evolution. In particular, it was
suggested that the winds may regulate the galactic gas supply and be the source of the heavy elements in the intergalactic
gas. Dr. Akimi Fujita, a postdoctoral fellow in Professor Martin’s group, collaborated with scientists at Los Alamos National
Laboratory to calculate the dynamical evolution of the galactic wind, now calibrated via the group’s observations, using a
supercomputer. Her results, which agree with those of several other groups, suggest that the elements may be spread over
distances 10 to 50 times larger than directly seen to date.
Most recently, Professor Martin’s group has focused on developing new diagnostics of galactic winds that could be used to
calibrate their strength and impact on galaxy evolution over cosmic time. Several times a year they make new measurements
with spectrographs on the twin Keck telescopes on the
summit of Mauna Kea in Hawaii. There, high above
the clouds and much of the atmospheric turbulence,
the astrophysicists spread the light from distant galax-
ies out into its constituent colors. They measure the
Doppler shifts of dark lines in the spectra, imprinted
by cold, interstellar gas atoms, and compare these
velocities to that of the galaxy, determined by more
lines from the hot photospheres of stars. In this exper-
iment, the starlight acts like a light bulb behind the
galactic wind, which becomes too dilute and dim to
detect by its own light. Over several years, the group
used spectrographs at Keck Observatory to measure
the dark absorption lines in starburst galaxies having
a broad range of escape velocities. The dissertation
of UCSB Physics graduate student Colleen Schwartz
produced critical measurements for small, low-mass
galaxies that showed a correlation between the Dop-
pler velocity of the outflow and the galactic escape
velocity. This empirical recipe was rapidly integrated into cosmological models attempting to describe galaxy evolution.
It now appears that the galactic winds remove a significant mass of heavy elements from galaxies, particularly the very
numerous small ones. The first census of wind activity in the local universe has just been published in the doctoral dissera-
tation of UCSB Physics graduate student Taro Sato, who finds the strongest winds in rapidly evolving galaxies. This result
strengthens claims that winds are an important process driving
such evolution.
Much remains to be learned about just how far galactic winds
transport these heavy elements. The UCSB group thinks the
answer lies in the physical properties of carbon- and oxygen-
polluted regions in intergalactic space. For two decades now,
other researchers have carried out a careful accounting of
these regions by observing the dark lines in quasar spectra that
are imprinted by clouds of intergalactic gas along our sightline.
Kurt Soto assisted with spectroscopic observations at the Keck
telescope, in collaboration with researchers at UC Berkeley and
the University of Victoria (Canada), to do simple tomography
of these regions with recently discovered groups of quasars.
First results appeared this fall and indicated that the typical
size of the polluted regions is about 30 times larger than the
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Recent breakthroughs in experimental cosmology have shown that the universe contains
very little normal matter. Measurements show the spatial curvature of the universe is flat, and it follows
from Einstein’s theory of General Relativity exactly how much mass (or equivalent energy) is required to
make it flat. Careful accounting of the stars and gas in galaxies and in this gas between the galaxies yields just
4% of the total. About a fourth of the total mass is in “dark matter” detected so far only by its gravitational
influence. The balance, i.e. most of the “stuff” in the universe, is in a mysterious form called simply “Dark
Energy” for want of any understanding at present. The standard model for structure formation in the universe includes the gravitational force of this Dark Matter and
the repulsive force of the Dark Energy. It successfully describes the large-scale distribution of galaxies and intergalactic gas, but predicts not only far more stars
(and gas) in galaxies than are observed but also far more galaxies than the universe appears to contain.
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Physics External Review
Approximately every seven years, each Department at UCSB
is reviewed. This is a lengthy and rigorous process that is
intended to ensure that the educational and research mis-
sions of the University proceed at the highest possible level
in each and every Department and Program. Last year, the
Physics Department underwent this review.
The review process is overseen the Program Review Panel
(PRP), which is a committee of the Academic Senate, and
which was chaired last year by Professor John Majewski of
the History Department. The process began with data col-
lection. First came raw numbers. How many undergraduate
students were majoring in physics over each of the past
seven years? How many graduate students did we have
each year? How many non-majors were taking our courses?
How many grant dollars were coming in? And so on. Next,
both graduate and undergraduate students were surveyed.
Students were asked to rate on a one-to-five scale their satis-
faction with all sorts of issues, ranging from “assistance with
planning your course of study” to “attitude of staff toward
undergraduates” to “the department as an intellectually
stimulating and exciting place for learning”. They were also
asked for open-ended comments on all these issues and any-
thing else of concern.
All of this information was compiled and collated by the PRP
and given to us to absorb and evaluate. The Department then
prepared two lengthy documents, in a process overseen by
Professor Jeff Richman: a Self Assessment and a Development
Plan. In the Self Assessment, we provided answers to a long
series of open-ended questions in five areas: the discipline of
physics in general and how our Department fits into the over-
all worldwide intellectual climate; the faculty and the nature,
breadth, and influence of their diverse research programs;
the graduate program and its goals and accomplishments;
the undergraduate program and its goals and accomplish-
ments; the available facilities and support services and how
well the needs of the Department are being met. We also
provided information on our extensive outreach activities to
the K-12 schools, high school teachers, and the general pub-
lic. In the Development Plan, we laid out where we would
like to be in terms of faculty, staff, students and facilities in
seven years, when our next review would nominally take
place. These documents (along with all the collated numbers
and student surveys) were reviewed by various groups such
as the campus’ Graduate and Undergraduate Councils, the
Executive Committee of the College of Letters and Science,
the Dean of Science, and the Dean of the Graduate Division,
all of whom provided comments and questions to be asked
of an External Review Committee (ERC) of three faculty from
other universities.
In a parallel process, the ERC was chosen. First, the Depart-
ment was asked to submit names of distinguished faculty at
other institutions who were then asked to nominate poten-
tial members of the ERC. The final selection of the ERC was
made by PRP in consultation with the Dean of Science and
the Executive Vice Chancellor (EVC) of the University.
We were extremely fortunate to have three eminent physi-
cists as our ERC: Marc Kastner, Professor and Head of the
Physics Department at MIT; Marjorie Shapiro, Professor and
Chair of the Physics Department at UC Berkeley; and Michael
Shull, Professor and past Chair of Astrophysics and Planetary
Science at the University of Colorado.
The ERC received the voluminous written material that had
been prepared, and visited UCSB in early February. They were
able to meet both individually and collectively with faculty,
staff, and students in the Department, as well as the Deans
of Science and the College of Creative Studies, the EVC, and
members of PRP. We had an engaging and informative visit.
We received their report in May. The ERC concluded that
“The UCSB Physics Department is among the best in the
United States [and] one of the jewels in the crown of the Uni-
versity. … The review committee came away with a strong
sense of admiration for this outstanding department, with a
strong commitment to first rate research and to both under-
graduate and graduate education. We commend the faculty,
the staff and the Department Chair on their hard work and
dedication.” The Committee also had a number of concerns
for the future: “If the Department is to maintain its current
strength, the University and the Department must work
together to craft solutions in the areas of research and teach-
ing infrastructure (the need for a new building), graduate
student support (funding required if UCSB is to be competi-
tive in attracting the best students) and faculty recruitment
(strategic hiring plans and priorities).”
We were very pleased to receive such a strong endorsement
from such a distinguished and well-informed committee. We
look forward to achieving the goals laid out in our Develop-
ment Plan and in their report. n
Alumni Spotlight
7
Alex Filippenko[
[continued on page 11]
From playing with magnets in sandboxes as a child to exploring the general field of science to conducting research
in astronomy and cosmology, UCSB alumnus Alex Filippenko is a world-renowned astronomer and prize-winning
professor of astronomy at the University of California, Berkeley.
Filippenko comes from a UC family; his parents were attending Berkeley when he was born, and moved to the Santa
Barbara/Goleta area when Alex was six.
His connection to UCSB started while still in high school – he won the College of Creative Studies (CCS) “Prize Exam”
in chemistry as a senior and continued those studies at UCSB, beginning as a CCS Chemistry major. It was not a big
leap to physics. “During my freshman year at UCSB, I realized that I was
really most interested in the physical aspects of chemistry, and especially
in physics,” he says. “Also, my interest in astronomy, which had been just
a hobby during high school, was steadily growing.”
It was all work and little play for Filippenko. “I took about twice the normal
load of units while I was an undergraduate,” he says. “Though this gave
me great breadth, I now realize that I should have taken fewer classes so
as to learn the material more deeply. Also, this would have given me some
free time; I had essentially no social life.”
Alex’s hard work did not go unnoticed. UCSB Physics professor Stanton
Peale (now emeritus and research professor) took note of the young
Filippenko. He was “willing to work very hard,” says Peale. “Each term
he would take about 30 quarter units, and
often end up with 6 hard physics problem
sets due each week. He could go a week with almost no sleep and still function. Yet he
maintained a GPA greater than 4.0 from the large fraction of A+ grades he earned.”
Filippenko was greatly inspired by Peale to become an astrophysicist. A few days prior
to Voyager 1’s historic encounter with Jupiter, Peale, with coauthors Patrick Cassen
and Ray Reynolds, published a paper suggesting rampant volcanism on the surface of
Jupiter’s moon, Io. Their prediction was confirmed in March of 1979 when Voyager 1’s
probe revealed active volcanoes on Io’s surface. “This prediction and confirmation had
a profound effect on me,” says Filippenko. “It showed me (vicariously) not only the thrill
of discovery, but also the power of physics and logical reasoning.”
After obtaining his BA in Physics (through CCS) at UCSB and PhD in Astronomy at
CalTech, Filippenko returned to UC Berkeley, this time as a faculty member.
“My primary areas of research are supernovae, active galaxies, black holes, gamma-ray
bursts, and observational cosmology. I am especially interested in using Type Ia super-
novae to determine the expansion history of the universe,” he says. His research “found
evidence that the expansion rate of the universe is speeding up, rather than slowing
down as had been expected.” This
discovery, which suggests that space
is filled with so-called “dark energy,”
was voted as the top “Science Breakthrough of 1998” by the
editors of Science magazine. Both research teams with which Fil-
Alex Filippenko’s research group: astro.berkeley.edu/~bait/kait.html
LCO Lectures: physics.ucsb.edu/lco.htmlCollege of Creative Studies: www.ccs.ucsb.edu
RELATED LINKS
Alex Filippenko with Professor Stanton Peale at the Santa Barbara Museum of Natural History (SBMNH) last May. Filippenko’s lecture “Dark Energy and the Runaway Universe” was presented in cooperation with the Las Cumbres Observatory Global Telesope Network, the UCSB Physics Department and the SBMNH.
Before/after images of SN 1998dh, obtained with the 0.76-m Katzman Automatic Imaging Telescope at Lick Observatory. Comparison of the apparent brightness of nearby and distant Type Ia supernovae indicates that the expansion of the Universe is currently accelerating, driven by mysterious “dark energy.”
Giving from Within
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Guenter Ahlers, UCSB experimental condensed matter physicist, explores critical phenomena (the behavior of materials undergoing a change in phase) and fluid mechanics (the non-linear response of fluids, pattern formation, the development of chaos in both space and time, and turbulence). He is recognized as an international leader in condensed matter physics, carrying out well-engineered, precise experiments that test our understanding of materials at a fundamental level. Ahlers has received numerous honors, including election to the National Academy of Sciences in 1982 and, most recently in 2007, the Fluid Dynamics Prize of the American Physical Society. He has been a Professor in the Department of Physics since 1979.
UCSB Physics professor Guenther Ahlers and his wife, June, have created a generous graduate endowment fund for the UCSB Physics Department, to be paid out in perpetu-ity after the Ahlers’ passings.
In making their decision, the Ahlers focused their giving on what they perceived to be the greatest need for UCSB Physics -- scholarships for graduate students. Adequate funding is “necessary to attract the best students” to UCSB, Ahlers says. “We get among the best applicants, but often lose them to our ‘competitors’ – that is, private universities that can offer significant financial incentives to potential students.” Ahlers believes that charitable donation is not only a way to “bring up” the department, but also to retain faculty. However, this needs to be a group effort. As Ahlers puts it, a single donation is merely a “drop in the bucket.”
Ahlers arrived in the US with ten dollars in his pocket and a desire to go far in his education – something he felt he couldn’t do in his native Germany in the unstable years following World War II. He stayed with a relative in Ohio while attending the University of Cincinnati. Eventually he earned his BA in Chemistry at UC Riverside, and his PhD in Physical Chemistry at UC Berkeley.
Starting in 1963, Ahlers held a technical staff position with Bell Laboratories in New Jersey. He had no intention of leaving until Vincent Jaccarino, a former UCSB Physics Professor (now emeritus), contacted him. Jaccarino had left Bell Labs ten years earlier and asked the reluctant Ahlers: “wouldn’t you like to come to UCSB?” Ahlers came to visit. Once he made the trip, he realized the potential of working at UCSB – including expanding his research team in a university set-ting. He joined the UCSB Physics Department in 1979.
Ahlers’ previous employment at Bell Labs played a key role in his financial future. Because of Bell Labs’ stock ownership plan, and an increase in the stocks’ value, Ahlers and his wife searched for the wisest method of investment. They established a charitable remainder unitrust (CRUT), a popular and flexible type of life income plan. A CRUT has many advantages, including no capital gains tax, a sizable tax deduction, a healthy return. It is regarded as a relatively “safe” investment.
They then decided to focus their giving on UCSB’s graduate department. “UCSB Physics is among the very best in the world,” says Ahlers. “However, it has extremely limited resources. It is hard to be compared to our private university peers, who have incredible endowments and fantastic resources.”
The Ahlers did not stop there. Guenther and June share a mutual passion for the arts, so a further expression of their generos-ity to UCSB was the recent donation of Affection, a bronze sculpture by renowned sculptor Allan Houser to the University Art
Museum. The piece resides in the entrance hall of UCSB’s Performing Arts building.
Ahlers was drawn to the “cause” because of his long history and personal involvement with the University of California and UCSB – both as alumnus and professor. His giving comes from the heart. “I’ve had a wonderful quarter-century here,” he says. “And UCSB is my home away from home.”
The Department of Physics is extremely grateful to the Ahlers for the establishment of the graduate endowment fund. The fund will undoubtedly play an important role in future graduate recruitment efforts. n
Guenther Ahlers ]
Guenther Ahlers’ research www.nls.physics.ucsb.edu
Planned Giving to UCSB www.ia.ucsb.edu/dev/planned.aspx
Contact UCSB Development www.ia.ucsb.edu/dev/contact.shtml
RELATED LINKS
Allan Houser’s Affection, donated by the Ahlers
to the University Art Museum.
Connections
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Thank you, Donors!WE APPRECIATE THE GENEROSITY of the people and institutions who donated funds to the UCSB Physics Department.
Mr. and Mrs. Joseph F. AlibrandiDr. and Mrs. Paul H. BarrettDr. Bronwen Brindley Dr. and Mrs. Guenter AhlersMr. and Mrs. Fred Cottrell Vasanti and Joel FithianFoundational Questions Institute (FQXi)Dr. Roger A. Freedman and Ms. Caroline RobillardGE Foundation
Calling All Physics Alumni
Kate Yarbrough n Surfers at Coal Oil Point Reserve, 2007
UCSB Alumni AssociationKeep your connection to UCSB by becoming a member of
the UCSB Alumni Association. New Life Members, in addi-
tion to becoming part of a useful community, receive a free
fine art print from award-winning Santa Barbara artist Kate
Yarbrough.
Join online at www.ucsbalum.com or call (�0�) ���-�20�.
Get Connected!Visit our Physics Alumni web pages for spotlights on
Physics alumni, more information about our services and
how to get involved with the UCSB Alumni community.
Find us online at physics.ucsb.edu/people/alumni
or email alumni@physics.ucsb.edu.
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Mr. Marc M. GorelnikMr. & Mrs. Kermit Harcos The Hertz FoundationDr. Surendar JeyadevDr. James J. LichterMr. Dale LowdermilkDr. Philip MartzenMr. Edward L. NoonMrs. Arnold NordsieckMr. Karl B. Runde
Santa Barbara FoundationSanta Barbara Womens ClubAlfred P. Sloan FoundationThe TABASGO FoundationMr. John L. WarrenDr. and Mrs. Albert D. WheelonDrs. Beth and Michael WitherellMr. and Mrs. James WoolfMr. and Mrs. Joseph Yzurdiaga
INTERESTED IN GIVING to UCSB Physics? With a tax-deductible donation (payable to UC Regents,) you can support endeavors such as Graduate Fellowships, Undergraduate Special Projects, or Community Outreach.
Please use the envelope included in this issue, or contact Dan Oh n (805) 451-4875 or (805) 893-7223 n dan.oh@ia.ucsb.edu
from 10/19/06 - 10/30/07
Image: a qubit wafer made in the John Martinis research group labs at UCSB. These test chips are used to measure two-qubit logic gates for a superconducting quantum computer. Much of the group’s effort is devoted to understanding the basic physics of decoherence (error) mechanisms in Josephson junction devices. The devices pictured here are made on a sapphire wafer because of its low dielectric loss which reduces decoherence. Photograph: Erik Lucero.
New GradLife webpageWe created the GradLife web page at www.physics.ucsb.edu/~gradlife as part of our mission to improve the overall Physics graduate student experience. Gradu-ate students naturally have many questions ranging from how they should go
about finding an advisor to how the advancement process works and what’s expected of them as teaching assistants, but the answers to many such questions were spread across a bunch of documents, many of which were buried deep within some Graduate Division website. So, we wanted to collect all of that information and also add a few things.
The other purpose of the website is to assist grads in being more con-nected to the university both socially and academically. On the site, we publicize our own events (such as pizza socials and gradloquiua) and maintain a set of calendars of academic events, which supple-ments the “official” Physics Department calendar.
Finally, we hope that the website will grow as new students con-tribute and rotate through the committee and we hope that it will become an increasingly helpful tool for UCSB physics grads.
-- Miles Stoudenmire, co-organizer, GradLife Committee
GradLife website: physics.ucsb.edu/~gradlife Department of Physics event page: physics.ucsb.edu/newsevents
Graduate Award Recipients 2006-07John Cardy Award: Brian Camley
Ferrando-Fithian Fellowship: Mariarosaria D’Alfonso, SungBin Lee
Wheelon Fellowship: Brian Maertz
Outstanding Teaching Award: Feraz Azhar
Outstanding Teaching Assistant Award: Matthew Block
Chair’s Certificate of AppreciationHead Teaching Assistant: Ian MorrisonGraduate Student Leadership and Service: Lisa Manning
Poster Day 2007
Approximately 60 prospective graduate students mingled with current grads, post docs and faculty among a sea of colorful research posters during the prospective student visit day in April 2007.
Student News
10
Arnold Norsieck Award
Randel Cotta
Outstanding Senior
Kiyotaka Akabori, Jeffrey Flanigan
Physics Highest Academic Honors
Jeffrey Flanigan, John Heron
Physics Academic Honors
Kiyotaka Akabori, Christopher Phelps, Samuel Rosenthal, Matthew Reed, and Elaine Turner
Physics Circus Awards
Diego Gavia, Ryan Hazelton, Susanna Kohler, Ian McFarlane, Joshua Stortz
Chair’s Certificate of Appreciation
Susanna Kohler, Ellie Newton (President and Vice President, Society of Physics Students)
Research Honors
Paul Hansma Lab: Davis Brimer, Federico Garza De Leon, Eugene Yurtsev, Jason Lulejian, Alexander Proctor
Elisabeth Gwinn Lab: Anthony Guerrero
Deborah Fygenson Lab: Jose Caro, Jr., Tich Do
Philip Lubin Lab: Daniel Petersen, Mark Croce, Jared Martinez, Elaine Turner, Brian Goss, Steffanie Hughes, Griffin Rowell, Sean Zumwalt, Ryan Moll, David Roozee, Jared Schmitthenner, Nile Fairfield, John Billings III
UCSB New Venture Competition
Most Fundable Idea: Davis Brimer and collaborator Alexander Proctor
Alumni Award: Davis Brimer and collaborator Alexander Proctor
Undergraduate Award Recipients 2006-07
Graduate Roundup
11
associated galaxies. This scale appears to be large enough
to require very strong winds, and the team hopes to learn
much more about the physical properties of these regions.
We do not yet understand, for example, just how much these
supernova-driven winds regulate the amount of star forma-
tion in galaxies or heat the intergalactic gas. New theoretical
predictions suggest that winds powered by accretion onto
supermassive black holes ought to be investigated as well.
As hard work and the Keck telescopes bring us closer to a
physical understanding of the life cycle of galaxies, further
surprises no doubt lie ahead. The UCSB astrophysicists hope
to remain well equipped to study them. The University of
California, California Institute of Technology, and the Asso-
ciation of Canadian Universities for Research in Astronomy
have designed a much more powerful telescope, the Thirty
Meter Telescope, an extremely large telescope based on 492
hexagonal-shaped mirror segments that stretch a total of 30
meters in diameter. Stay tuned for first light in 2016! n
Crystal Martin -- Galactic Winds (continued from page 5)
Alex Filippenko (continued from page 7)
Las Cumbres Observatory Lectures In collaboration with the UCSB Department of Physics and the Santa Barbara Museum of Natural History (SBMNH), the Las Cumbres Observatory Global Telescope Network (LCOGT) has established the annual Las Cumbres Observatory Astrophysics Lecture, bringing internationally renowned astronomers from around the world to Santa Barbara. This annual lecture series provides an opportunity for community members, students and scientists in Santa Barbara to interact with these high-
profile scientists from around the world and learn about the frontiers of the exciting fields of astrophysics and cosmology.
The second lecture, in May 2007, featured Dr. Alex Filippenko (above, center, with event co-organizers Tommaso Treu and Crystal Martin) of UC Berkeley on “Dark Energy and the Runaway Universe.”
LCOGT Lecture Series website: physics.ucsb.edu/newsevents/lco.html
lipenko was affiliated were recognized with the prestigious
2007 Gruber Cosmology Prize.
His approachable teaching style and dedication to his stu-
dents has continued to garner attention. He has won several
major awards for distinguished teaching and mentoring at
UC Berkeley. Informal student polls have rated him as the
“Best Professor” on campus five times. In 2006, he was
selected as the Carnegie/CASE Doctoral and Research Uni-
versities National Professor of the Year.
“I marvel at how Alex can make relatively complicated mate-
rial accessible to non-science majors and, for that matter to
the lay public,” says Peale. Filippenko’s accessible style has
made him a popular speaker. He has been featured on sev-
eral science documentaries, and has given well over 400
popular talks. In May 2007, Filippenko was invited to present
the annual Las Cumbres Observatory Global Telescope Net-
work Science public lecture at the Santa Barbara Museum of
Natural History; he spoke on “Dark Energy and the Runaway
Universe” (see sidebar, this page).
Always busy, Filippenko continues his research at Berkeley.
His team has constructed the Katzman Automatic Imaging
Telescope, a 0.76-meter robotic telescope that “observes
automatically while we sleep; it is used primarily to discover
new supernovae and to monitor variable or ephemeral
objects.”
And what does the future hold? “I’ll continue teaching and
conducting research. I also plan to write at least one popular-
level book on my studies of supernovae and the accelerating
expansion of the universe.” n
Editor: Becky Haycox
Contributing Writers: Claudio Campagnari, Nancy Fraser, Becky Haycox, Crystal Martin, Mark Srednicki
Layout & Production: Becky Haycox
Department Business Officer: Nancy Fraser
Department Chair: Mark Srednicki
University of California
Department of Physics
Mail Code 9530
Santa Barbara, CA 93106-9530
FALL 2007
CHANGE OF ADDRESS? Please contact UCSB Physics
at (805) 893-3888.
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Image: A bundle (~30 microns long) of DNA nanotubes that self-assemble from syn-thetic strands of DNA visualized by fluorescence microscopy. These structures can be used to better understand the phenomenon of counter-ion condensation and the molecular structure of the DNA nanotubes. Photo by JA Caro, BSc ’07 in the Fygenson Lab.
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